JP2019517953A - Drive system control method and drive system - Google Patents

Abstract

The invention relates to a control method of a drive system comprising at least two drive units (20), each paired with at least one control unit (22). The total target torque (30) is calculated by the master control unit (22a) and the total target torque (30) is calculated by the master control unit (22a) for the individual target torque (32) for each of the drive units (20) And the drive units (20) are controlled by the control unit (22) assigned to them, based on the associated individual target torque (32). The invention is characterized in that the respective threshold torque (34) of the drive unit (20) is determined and taken into account by the master control unit (22a) in distributing the total target torque (30). Do. [Selected figure] Figure 1

Description

  The invention relates to a control method of a drive system comprising at least two drive units, each being paired with at least one control unit. The invention also relates to a corresponding drive system.

  The drive system of the motor vehicle is controlled by at least one control unit, a so-called engine control unit, as a function of external constraints, in particular the position of the accelerator pedal set by the vehicle driver.

  As drive systems in modern vehicles are constantly increasing in complexity, the computing power required to handle engine control while operating the drive system is also increasing. This applies in particular to the drive system of a motor vehicle which combines a plurality of drive units. An example of this is a so-called hybrid car. A hybrid vehicle combines at least one internal combustion engine and at least one electric drive motor, the individual drive powers being adapted to be linked to one another. In particular, in such a drive system, the computing power required to control the various drive units becomes so large that it is not possible to provide a single engine control system that can handle this computing power. . One reason for this is, for example, the limited space in the engine compartment of the corresponding vehicle. This makes it impossible to incorporate an engine control system that has sufficient capacity and thus a relatively large volume. Thus, in general, for a drive system having a plurality of drive units, a plurality of control units are used, at least one of which is paired with at least one drive unit, and they are interconnected It is done. As such, one of the control units is configured to operate as a master control unit, acting at a higher level than other control units, often referred to as slave control units.

  For example, German Patent Application DE 102 24 2430 A1 describes a method of controlling a drive system of a motor vehicle. Depending on the position of the accelerator pedal, the total torque (total torque) is determined, and the torque interface (torque interface) sets the total torque to the target torques for torque-controlled aggregates. After division, the desired torque is then transmitted to the individual control units of these clusters. The torque control assembly may in particular be an internal combustion engine and an electric drive.

  German Patent Application DE 102008041463 also describes a drive system for a hybrid vehicle. The drive system comprises a combustion engine having an associated engine control as well as a plurality of electric drive motors having an associated control unit. One of these control units is designated as the master control unit. The master control unit sends the torque request sent by the engine control unit to the other control unit paired with the electric drive motor.

  DE 102010038995 A2 has two banks of cylinders, each paired with a control unit to control the operation of the associated bank of cylinders An internal combustion engine is disclosed. The control unit associated with the bank of the first cylinder acts as a master control unit and sends the other (slave) control unit a request for disconnecting the bank of the second cylinder.

  DE 102013208022 A1 is based on rolling back on slopes by applying torque to the wheels using an electric traction motor. Hybrid vehicles are disclosed to prevent. If the temperature of the traction motor or the associated power converter exceeds the limit temperature, the traction motor is disconnected and, instead of the traction motor, the internal combustion engine is connected to the slipping drive wheels to prevent the occurrence of rollback. The hybrid vehicle control system includes a control unit paired with an internal combustion engine, a control unit paired with a traction motor, and a higher order vehicle control unit that provides overall control of both units.

German Patent Application Publication No. 10222430 German Patent Application Publication No. 102008041463 German Patent Application Publication No. 102010038995 German Patent Application Publication No. 102013208022

  In order to adjust the control units linked to one another with a common objective, ie to carry out the desired driving conditions by the driver of the vehicle represented by the specific position of the accelerator pedal, It is necessary to consider the additional parameters of This will invariably lead to corresponding error messages, reduced driving forces and / or errors that result in reduced driving comfort provided by the drive system.

  Based on this prior art, the object of the present invention is an improvement of the control method of a drive system comprising at least two drive units, each paired with a control unit.

  This object is achieved by the method according to claim 1. The implementation of a drive system suitable for carrying out such a method is the subject of claim 10. Advantageous embodiments of the drive system according to the invention and preferred embodiments of the drive system according to the invention are the subject matter of the further claims and / or result from the following description of the invention.

In a control method of a drive system comprising at least two drive units, each paired with at least one control unit,
The total target torque is calculated by the master control unit
The total target torque is subdivided by the master control unit into individual target torques for each of the drive units,
The control method of the drive system in which the drive unit is controlled by the control unit assigned thereto based on the associated individual target torque is:
A respective threshold torque of the drive unit may be determined and taken into account by the master control unit in distributing the total target torque. The determination is preferably made by the control unit associated with the drive unit, which in turn transmits this to the master control unit.

  The present invention is not in a situation in which one or more drive units achieve the individual target torque currently assigned to them due to circumstances or operating conditions (not in a position), but in a currently assigned manner In particular when adjusting the individual target torques determined by the master control unit based on the total target torque or determined by the control unit paired with these drive units if it must be in a situation where Based on the finding that

  In the following, “threshold torque” is the maximum torque that can be generated by the drive unit, depending on the current operating state. This may be at least temporarily less than the absolute maximum torque that the drive unit can achieve based on its design, due to different factors involved. The threshold torque therefore does not have to correspond to the actual torque currently supplied by the drive unit. Input factors that will result in threshold torques smaller than the absolute maximum torque are, for example, relatively low and / or high ambient temperatures, relatively low and / or high component temperatures, corresponding drive units Misbehavior of individual parts and how much they are working in a particular working condition (eg, as in the case of a drive unit that can only be operated temporarily in a clear overload condition (overboost)), etc. It is.

  The drive system according to the invention comprises at least two drive units, each being a drive system paired with at least one control unit, comprising a master control unit, associated with the master control unit and the drive unit The control unit is characterized in that the control method according to the invention is programmed to be executed by them.

  The master control unit may be one of the control units paired with any of the drive units and thus acts as a master control unit as well as a corresponding control unit paired with one of the drive units. One of the control units may be paired with each drive unit, but it is also possible to have a master control unit that controls all these control units.

  The method according to the invention can advantageously operate the drive system according to the invention. If the individual target torque determined for the drive unit exceeds the associated threshold torque, the individual of the other drive units (at least one, one or more, or all if there are more drive units) This is to add the corresponding torque difference to the target torque as much as possible, preferably completely. The individual target torque that is actually transmitted to the associated drive unit having a relatively small threshold torque may be limited to the threshold torque. However, this is not absolutely necessary. In any case, in the related operating state, the related drive unit does not generate an actual torque exceeding the threshold torque (thereby the individual target torques obtained by dividing the total target torque by the master control unit are totaled , Can be more than the total target torque). Operating one of the drive units with an actual torque limited to the associated threshold torque (where this threshold torque is temporarily lower than the individual target torque determined for the drive unit And the adverse effect on the drive characteristics of the entire drive system can be avoided. This is because the reduced and limited actual torque of the drive unit is compensated by one or more other drive units.

  In a preferred embodiment of the method according to the invention, the master control unit may determine the actual torques associated with the drive units and determine therefrom the total actual torque. The total actual torque determined thereby can advantageously be transmitted to a functional element (such as a controller for an electronic stability program or a controller for an automatic transmission). A functional element, such as a controller for an electronic stability program or a controller for an automatic transmission, can advantageously be transmitted such that its functionality is controlled as a function of the total actual torque. As such, the functionality of the functional elements can be controlled as a function of the total actual torque.

  As a result, for example, a high level of torque output accuracy can be achieved, which allows the automatic transmission to shift gears more smoothly.

  If such a procedure is preferably carried out, the total desired torque is determined as a function of the parameters transmitted by the functional element to the master control unit and can advantageously be carried out. In particular, the determined total target torque may be split as optimally as possible into the individual target torques assigned to the individual drive units.

  The method according to the invention can be implemented particularly advantageously in a drive system consisting of at least one internal combustion engine as drive unit and at least one electric motor as additional drive unit. Although such hybrid systems require significant levels of computer control power, not only can they be advantageously operated by a plurality of interconnected control units, but it is particularly advantageous that the threshold torque assigned individual It is possible to compensate the torque difference of the drive unit below the target torque by means of the corresponding other drive unit.

  Furthermore, the method according to the invention can be particularly advantageously implemented for drive systems which are subdivided into several sub-engines, each being paired with a control unit. Such an internal combustion engine may be divided into sub-engines. For example, corresponding individual cylinder banks formed in internal combustion engines of type V, type W, or boxer design.

  With such a design, the control system of the invention has a particularly advantageous effect on such a drive system. The torque difference of the first sub-engine (whose threshold torque and hence its maximum achievable actual torque is temporarily smaller than the respective target torque assigned to it) causes deterioration of the overall operating characteristics of the internal combustion engine In particular, this leads to a deterioration in driving comfort and / or to a fault diagnosis (in particular, for example, detecting a misfire but not actually occurring). This is prevented by keeping the actual torque substantially the same by limiting the individual target torque of the second sub-engine to the threshold torque of the first engine section. Can.

  Thus, in a preferred embodiment of the method according to the invention for controlling such a drive system, the individual target torque of the first sub-engine is that of the sub-engines (two or more sub-engines, preferably all other sub-engines) The individual target torque transmitted to the corresponding drive unit may be reduced or limited to the threshold torque of the first sub-engine if it has exceeded the associated threshold torque determined for . While this may in fact result in a reduction of the actual torque generated by the sub-engine as a whole, this may weaken the operating characteristics of the aggravated internal combustion engine and / or reduce false fault diagnosis. preferable.

  The actual torque generated entirely by one of the sub-engines will be of little concern. In particular, as provided in a preferred embodiment of the drive system according to the invention, not only an internal combustion engine with several sub-engines, each suitable as a drive unit, but also at least one electric motor operating as a drive unit If provided, such an embodiment of the drive system is to be compensated by the electric motor, thus enabling a reduction of the actual torque generated by the entire sub-engine. Thus, in a preferred embodiment of the method according to the invention for the control of such a drive system, if the individual target torque determined for the first sub-engine exceeds the associated threshold torque, The individual target torque determined or determined for the second engine section is reduced or limited to the threshold torque of the first sub-engine to the electric motor individual target torque, preferably as complete as possible , The sum of the torque differences of the sub-engines or modules may be added.

  Furthermore, the invention relates to a computer program comprising program code for performing the method according to the invention when the computer program is run on a computer.

  The indefinite article ('a' or 'one') is to be understood as such and does not represent a number, particularly in the context of the claims, and in the description which generally describes the claims. It must be understood. Similarly, components so designated should be understood as existing at least once and possibly several times.

  The invention will be explained in more detail in the following using the exemplary embodiments represented in the figures.

FIG. 1 is a schematic view and embodies the method according to the invention with the drive system according to the invention.

  FIG. 1 shows a drive system according to the invention with an internal combustion engine 10 and an electric motor 12 provided as a drive motor. Although not shown, a drive system may be provided to drive the hybrid vehicle. In the hybrid vehicle, the internal combustion engine 10 and the electric motor 12 (alternatively or in cooperation) may supply power to propel the vehicle. Furthermore, FIG. 1 shows the various steps in the procedure of carrying out the control method according to the invention for controlling a drive system.

  The internal combustion engine 10 is known, for example, in the form of a conventional piston reciprocating engine operating in a gasoline or diesel cycle. It has a total of 12 cylinders arranged in the so-called W-shape. Thus, the internal combustion engine 10 is configured as two banks with cylinders 14. Each bank has six cylinders 16 and is arranged in two offset rows and hence in a thin V-shaped layout. Elements constituting the two banks of the cylinder 14 and the further functional components (not shown) of the internal combustion engine associated therewith (in particular, the gas exchange valve mechanism (intake valve, exhaust valve and valve actuation mechanism) ) Constitute sub-engines 18 respectively. The plurality of sub-engines 18 together with the electric motor 12 constitute one drive unit 20 of the drive system of the present invention.

  The control unit 22 is paired with each of the drive units 20, and the control unit 22 assigned to the first sub-engine 18 (the upper sub-engine 18 in FIG. 1) of the internal combustion engine 10 is a master control unit. Designated as 22a and configured.

  In carrying out the control method of the invention for controlling the drive system, in a method step S1 the master control unit 22a calculates the value of the total target torque 30 which can be used in the drive system for driving the motor vehicle It is planned to do. The calculation of this total target torque 30 is mainly in response to a signal 44 indicating the position of the accelerator pedal 24 operated by the driver of the motor vehicle, and of the electrical stability program controlled by the control device 26. A manual or automatic gearbox 28 is generated as a response to signal 44 indicating which gear and other operating conditions, resulting from intervention or non-intervention.

  The anti-slip device includes controlling the brakes for the purpose of stabilizing the drive and, where appropriate, also controlling the driving torque of the individual wheels of the motor vehicle. The transmission 28 motorizes the drive speed (and hence the drive torque) from one or more output shafts or shafts of the internal combustion engine 10 and / or the electric motor 12 at various alternative gear stages. Work to transmit to the drive wheels of the

  Furthermore, in method step S2, the master control unit 22a divides the value calculated as the total target torque 30 into individual target torques 32 assigned to the three drive units 22 and controls the corresponding values to the other (slave) Send to unit. Then, based on these values for the individual target torque 32, all three control units start the actuator (not shown) of the drive unit. The corresponding actuators of the two engine sections 18 of the internal combustion engine 10 are control valves (throttle valves) integrated into the fuel injectors (e.g. each inlet gas line of the sub-engine 18) ), A phase angle adjusting device and / or a cam switching device of a valve timing mechanism, and / or a device for controlling the through-flow of the compressor, and / or for example, a so-called VGT device It may be a turbine of an exhaust gas turbocharger of the form of. The corresponding actuator of electric motor 12 may be a voltage regulator (e.g., a voltage is applied to electric motor 12 in a controlled manner).

  The drive unit 20 further comprises a number of sensors (not shown) which operate to determine specific operating parameters of the drive unit. Examples of suitable sensors used for the engine section 18 of the internal combustion engine 10 are: speed sensors, location and position sensors (for example control valves (throttle valves) integrated in the gas inlet line), Cylinder pressure sensors, temperature sensors, and flow measurement sensors (such as, for example, thermoelectric anemometers). Examples of suitable sensors used for the electric motor 12 are speed sensors and temperature sensors.

  The sensors assigned to the individual drive units 20 transmit their measurements to the associated control unit 22. The control unit 22 evaluates them in the next method step S3 and derive therefrom the value of the threshold torque 34 of the associated drive unit 22. The threshold torque is the maximum torque that can be generated by the individual drive unit 20, depending on the current operating conditions. The values of these threshold torques 34 are transmitted by the two slave control units 22b to the master control unit 22a and are subsequently calculated, as are the values for the threshold torques of the drive unit 20 associated with the master control unit 22a. The total target torque 30 is taken into account when dividing into individual target torques 32 assigned to the individual drive units 20. The same applies to the value defining the amount of actual torque 36 generated by the individual drive units 20.

  The total actual torque 42 is designed as a skid control device 26 and / or a transmission 28 (in particular as an automatic transmission 28) for use in adapting the skid prevention device and / or the operation of the transmission 28. Or may be determined by the engine control system from the sum of the actual torque 36 sent to the controller of the transmission 28).

  If multiple values for the threshold torque 34 of the engine section 18 of the internal combustion engine 10 have been transmitted, these values may be stepped before considering them in dividing the total target torque 30 into the individual target torques 32. In S 4, it may be linked with the total threshold torque 38 of the internal combustion engine 10.

  Data may be transmitted (40) between the control units 22, for example by means of a CAN bus.

10 internal combustion engine 12 electric motor 14 cylinder bank 16 cylinder 18 sub engine 20 drive unit 22 control unit 22a master control unit 22b slave control unit 24 accelerator pedal 26 control device 28 transmission 30 total target torque 32 individual target torque 34 threshold torque 36 Actual torque 38 Total threshold torque 40 Data transmission 42 Total actual torque 44 signal

Claims (12)

Method of controlling a drive system comprising at least two drive units (20), each paired with at least one control unit (22),
The total target torque (30) is calculated by the master control unit (22a),
Said total target torque (30) is subdivided by said master control unit (22a) into individual target torques (32) for each of said drive units (20);
A control method of a drive system in which the drive unit (20) is controlled by the control unit (22) assigned thereto based on the associated individual target torque (32),
A respective threshold torque (34) of the drive unit (20) is determined and taken into account by the master control unit (22a) in distributing the total target torque (30) Drive system control method.   If the individual target torque (32) determined for the drive unit (20) exceeds the associated threshold torque (34), the determined individual target torque (32) of the other drive unit 2. A control method according to claim 1, characterized in that the corresponding torque difference is added as much as possible.   The master control unit (22a) determines a plurality of actual torques (36) associated with the drive unit (20), and based on these, a total actual torque (42) is determined. The control method according to claim 1 or 2. The total actual torque (42) is transmitted to the functional element,
A control method according to claim 3, characterized in that the function of said functional element is controlled by said total actual torque (42).   5. Control method according to claim 4, characterized in that the total target torque (30) is determined as a function of the parameters transmitted by the functional element to the master control unit (22a).   6. A control as claimed in any one of the preceding claims, characterized by the implementation of a drive system having an internal combustion engine (10) as said drive unit (20) and an electric motor (12) as said drive unit (20). Method.   2. A drive system comprising an internal combustion engine (10) subdivided into a plurality of sub-engines (18) corresponding to said drive unit (20) to which said control unit (22) is assigned. The control method according to any one of items 6 to 6.   If the individual target torque (32) determined for the first sub-engine (18) exceeds the associated threshold torque (34), it is determined for the second engine section (18), or The control method according to claim 7, characterized in that the determined individual target torque (32) to be determined is reduced or limited to the threshold torque (32) of the first sub-engine.   If the individual target torque (32) determined for the first engine section (18) exceeds the associated threshold torque (34), then it is determined for the second sub-engine (18) Alternatively, the individual target torque (32) to be determined is reduced or limited to the threshold torque (34) of the first sub-engine (18), and the individual target torque of the electric motor (12) As far as possible, the sum of the torque differences of the sub-engines is added, and any one, claim 6 or claim 8 as claimed in any one of claims 2 and 2 dependent on claim 2. Control method. A drive system comprising at least two drive units (20), each paired with at least one said control unit (22),
It has a master control unit (22a),
The master control unit (22a) and the control unit (22) associated with the drive unit (20) are programmed such that the control method according to any one of the preceding claims is performed by them A drive system characterized by   11. The drive system according to claim 10, characterized by an internal combustion engine (10) as the drive unit (20) and an electric motor (12) as the drive unit (20).   The internal combustion engine as claimed in claim 10 or 11, characterized in that it comprises an internal combustion engine, each of which comprises a drive unit (20), each subdivided into a plurality of sub-engines (18) associated with the control unit (20). Drive system.

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